PH 404 Acoustics Winter 2011-2012 M.
J. Moloney
Homework Assignments
Problem Set 1. Due Friday December 2, 2011
- Text 1.1
- Text 1.2
- Text 1.3
- Text 1.5
- Text 1.7
- (For graduate students: Text 1.6)
Problem Set 2 Due Tuesday December 6, 2011
- Text 1.10
- Text 1.14
- Text 1.17
- Text 1.20
- Text 1.21
- Text 1.25
Problem Set 3 Due Monday December 12, 2011 (1st
Exam is Friday December 16, 2011)
- Text 2.2. Make an Excel
animation for this wave.
- Text 2.6
- Text 2.9. Make sketches of n = 2 and several m =
1,2,3,4.
Then argue for the value of each integral.
- Text 2.12
- Text 2.16
- (For graduate students: Text 2.15. At very low frequencies, this
mass
will
simply swing back and forth like a pendulum, so your equation for omega
ought (at low frequencies) to give the frequency of a pendulum.)
Problem Set 4 Due Monday January 9, 2012
- A rectangular membrane has length Ly = 0.40 m and width Lx = 0.20
m.
Its
lowest resonant frequency is 126 Hz. This membrane is given a sharp
blow
so that a small region between x = 0.07 m and 0.11m and between y =
0.17
m and 0.23 m is given a velocity v =0.40 m/s while the rest of the
membrane
is at rest. Find the coefficients of the 6 lowest-frequency modes of
this
membrane. This requires an analysis like was done in Section 2.5, pp.
47-49.
You will have to carry out integrals in Maple over both x and y.
- Text Prob 3.3
- Text Prob 3.7
- Convert the strpulse.mws file (emailed) to one where the pulse
reflects from the boundaries without flipping over.
Problem Set 5 Due Monday January 16, 2012
- Work out the odd-symmetry solutions for the flexural vibrations
of a
rod
or bar free at both ends
- Write down the odd-symmetry wave functions
- Express the y'' = 0 boundary condition at +/- L/2, and that for
y''' = 0.
- From these two (y'' = 0, y''' = 0) write down the equation in
kL/2 implied by satisfying free-end
boundary
conditions
- Find the lowest two odd-symmetry frequencies for a 12.7-mm
diameter aluminum bar 0.8 m long.
- Use the maple animation of a pulse at x = 8 m at t=0 on a 16-m
long wire to observe the waves reaching x = 12 m. The
pulse is made up of 500 fourier components, each frequency of which
depends on k^2. The waves start at x = 8.0 m and t = 0. Single-stepping
through it (at 1 ms/ per step) will let you observe the arrival of
various frequencies, each of which travelled about 4 m. You should see
the high-frequency, short-wavelength waves arrive first, and lower
frequencies later.
Record the measurements you make, and verify that the velocity of the
arriving waves is the 'group velocity' Explain what you measured, and
show a sample calculation. (Remember k = 2 Pi / wavelength.).
- Give your work and answers to the three question on the Stress
and strain, bar vibrations handout. (The answers are hiding under the
boxes, but don't peek till you work them out.)
- Text problem 5.3
- Text problem 5.5
- Text problem 5.6
Problem Set 6 Due Monday January 23, 2012
(Exam 2 will be
Thursday January 26, 2012)
- Text problem 6.2
- Text problem 6.3
- Text problem 6.4
- Text problem 6.6
- Use the emailed audacity files for the 0.500 m 1/2" diameter
steel drill rod to pull up the lowest four resonant frequencies. This
bar is free at both ends, supported by very light sewing thread. We
will get an 'exact' bar velocity from class/lab, and it will be quite
close to 5000 m/s. Calculate the four lowest flexural bar
frequencies from the theory and make a table with calculated and
measured bar freaquencies. Two of the lowest ones will be 'even' modes
and two will be 'odd'. Download Audacity 1.3 beta if you don't
already have it.